Your search keyword '"HELIUM plasmas"' showing total 1,790 results

1. The distribution and segregation behaviors of helium in tungsten Σ5(310)/[001] grain boundary region: A first-principles study.

Author

Wu, Mingyu, Zhang, Yujuan, Li, Yungang, Hussain, Muhammad Irfan, Jin, Jingyuan, Li, Sifan, Zhang, Yu, and Ge, Changchun

Subjects

*CRYSTAL grain boundaries, *TUNGSTEN, *HELIUM, *DENSITY of states, *ORBITAL hybridization, *HELIUM plasmas, *TUNGSTEN alloys, *HELIUM atom

Abstract

In this work, the distribution and segregation behaviors of helium (He) and the effect of yttrium (Y) on these behaviors in the symmetrical tilt tungsten (W) Σ5(310)/[001] grain boundary (GB) region were studied using first-principles calculations. The results revealed that the GB has a significant impact on the behaviors of He in W. The solution and segregation energies of He in the W Σ5(310)/[001] GB region increase with increasing the distance from He to the GB and are inversely proportional to the effective electrons of He. The density of states analysis showed that the GB can suppress partial hybridization between He and W atoms. In addition, we find that the strengthening element Y facilitates the dissolution of He in the W GB region. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cone array formation on Si surfaces by low-energy He plasma irradiation with magnetron sputtering pre-deposited Ta.

Author

Liu, Zhe, Li, Long, Gao, Zeshi, Chen, Ze, Yin, Chao, Mao, Shifeng, Kajita, Shin, Ohno, Noriyasu, and Ye, Minyou

Subjects

*HELIUM plasmas, *TRANSMISSION electron microscopes, *CONES, *MAGNETRON sputtering, *SCANNING electron microscopes, *IRRADIATION, *ION beams

Abstract

Low-energy ion beam irradiation, combined with the introduction of impurities, presents a promising approach for nanopatterning silicon (Si) surfaces. In this research, we investigate the surface evolution of Si (100) surfaces irradiated by 75 eV helium (He) plasma, in the presence of tantalum (Ta), traditionally regarded as an impurity incapable of initiating pattern formation, as evidenced in prior studies. The Ta impurities are pre-deposited onto the Si surfaces using the magnetron sputtering method, which offers a more controlled and quantifiable approach compared with the conventional co-deposition route. After irradiation at 800 K, dense cone arrays are produced on the Si surface. The growth of the cones is explored for fluence spanning (1–10) × 1025 m−2. The cross-sectional scanning electron microscope images indicate that the cone lengths and base width are well characterized by t1/2 dependence. The kinetics of the cone growth follow Fick's law, characterized by an effective diffusive mechanism with the coefficients of diffusion: D = 6.49 ± 0.83 × 10−16 m−2 s−1. Transmission electron microscope observations reveal that the cone has distinct inner and outer parts with different microstructures and a clear interface. The growth mechanism of these cones is elucidated as a composite process involving preferential sputtering, the destabilizing influence of He bubbles, and the migration of adatoms. [ABSTRACT FROM AUTHOR]

Published

2024

3. Research on the characteristics of the Helium plasma beam in HIT-PSI.

Author

Huang, Tao, Nie, Qiuyue, Jiang, Tao, Chen, Cheng, Liu, Yang, Gao, Jinming, Cai, Laizhong, Zhao, Xu, and Wang, Xiaogang

Subjects

PLASMA-wall interactions, HEAT flux, HELIUM plasmas, INFRARED spectroscopy, FUSION reactors

Abstract

As a high heat flux linear plasma device designed for studying divertor materials in future fusion reactors, HIT-PSI(Plasma Surface Interaction device at Harbin Institute of Technology) has been successfully constructed and has maintained stable operation since its completion. The characteristics of He plasma beams in HIT-PSI are investigated by emission spectroscopy and an infrared camera, with preliminary irradiation experiments conducted by bombarding tungsten with the beam. For relatively conservative discharge parameters, HIT-PSI achieved a steady-state heat flux capacity of ∼40 MW/m2 using infrared measurements, with the full width at half maximum (FWHM) of the heat flux beam reaching 4 mm. These characteristics make HIT-PSI an advanced platform for testing divertor materials and plasma-facing components, providing essential experimental supports for research and development of high-performance divertor materials. [ABSTRACT FROM AUTHOR]

Published

2024

4. Helium line emission spectroscopy to measure plasma parameters using modeling and machine learning in low-temperature plasmas.

Author

Kajita, Shin and Nishijima, Daisuke

Subjects

*MACHINE learning, *EMISSION spectroscopy, *PLASMA spectroscopy, *HELIUM, *RADIATION trapping, *HELIUM plasmas

Abstract

Line intensity ratios (LIRs) of helium (He) atoms are known to depend on electron density, n e , and temperature, T e , and thus are widely utilized to evaluate these parameters, known as the H e I LIR method. In this conventional method, the measured LIRs are compared with theoretical values calculated using a collisional-radiative (CR) model to find the best possible n e and T e . Basic CR models have been improved to take into account several effects. For instance, radiation trapping can occur to a significant degree in weakly ionized plasmas, leading to major alterations of LIRs. This effect has been included with optical escape factors in CR models. A new approach to the evaluation of n e and T e from He I LIRs has recently been explored using machine learning (ML). In the ML-aided LIR method, a predictive model is developed with training data, which consists of an input (measured LIRs) and a desired/known output (measured n e or T e from other diagnostics). It has been demonstrated that this new method predicts n e and T e better than using the conventional method coupled with a CR model, not only for He but also for other species. This review focuses mainly on low-temperature plasmas with T e ⩽ 10 eV in linear plasma devices. [ABSTRACT FROM AUTHOR]

Published

2024

5. Studies on the spatial evolution of pulsed helium plasma.

Author

Singha, S., Ahmed, A., Borthakur, S., Neog, N. K., and Borthakur, T. K.

Subjects

*PLASMA astrophysics, *HELIUM plasmas, *PLASMA temperature, *PLASMA density, *DENSE plasmas

Abstract

The high‐density transient plasma, streaming from a pulsed plasma accelerator (PPA), was diagnosed with a Triple Langmuir probe (TLP) for spatial mapping of the stream in terms of plasma density and temperature. A contour plot for density and temperature shows a distinct form of a highly dense island of plasma with varied plasma temperatures. The formation of such highly dense islands can be correlated with the formation of distinct plasma structures, as observed in astrophysical plasmas and fusion plasma. The results of TLP were supported by the intensity variation derived from signals of a photodetector system. The plasma stream imaged with high‐speed video camera also showed the density fluctuation inside the plasma stream. The estimated maximum density and temperature were ∼7.2 × 1020 m−3 and ∼28 eV, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

6. Deposition of Thin Films From HMDSO Utilizing the Vacuum UV Radiation From an Atmospheric Plasma.

Author

Winzer, Tristan and Benedikt, Jan

Subjects

*ATMOSPHERIC radiation, *ULTRAVIOLET radiation, *HELIUM plasmas, *THIN film deposition, *INFRARED spectra

Abstract

ABSTRACT This study presents a source for studying thin‐film deposition utilizing vacuum UV (VUV) radiation from a remote argon or helium atmospheric plasma to initiate photochemistry in the precursor gas. We aim to assess how this radiation affects the deposition process and film structure while avoiding deposition inside the plasma source or particle formation. Deposition occurs where radiation interacts with the precursor and the growing film, as well as further downstream. The measured film properties clearly show that photon interaction with the film has a significant effect. Using hexamethyldisiloxane (HMDSO) as a precursor, we achieved nearly carbon‐free silicon dioxide ( SiO 2 ${\text{SiO}}_{2}$) film growth due to photodesorption of hydrocarbons from the growing film, as confirmed by infrared spectra and positive ion mass spectrometry. [ABSTRACT FROM AUTHOR]

Published

2024

7. Radiation Effects in Tungsten and Tungsten-Copper Alloys Treated with Compression Plasma Flows and Irradiated with He Ions.

Author

Ryskulov, Azamat, Shymanski, Vitaliy, Ivanov, Igor, Amanzhulov, Bauyrzhan, Dauhaliuk, Anastasia, Uglov, Vladimir, Temir, Adilet, Astashynski, Valiantsin, Sapar, Asset, Kuzmitski, Anton, and Ungarbayev, Yerulan

Subjects

*PLASMA flow, *TUNGSTEN alloys, *HELIUM ions, *SCANNING electron microscopy, *X-ray microscopy, *HELIUM plasmas

Abstract

The paper presents the results of studying the structure and phase state of tungsten and tungsten-copper alloy after pulsed action of compression plasma flows and irradiation with helium ions. The compression plasma flows were used to modify the surface layer of tungsten, as well as to create an alloy based on tungsten and copper. Using scanning electron microscopy and X-ray structural analysis, the formation of radiation defects on the tungsten surface was detected in the form of local areas of exfoliation and destruction, which begin to form at helium ion irradiation doses of 2 × 1017 cm−2. It is shown that preliminary plasma treatment of the surface in the melting mode leads to the complete disappearance of surface radiation defects up to a dose of 2 × 1017 cm−2, which may be associated with the formation of a fine-crystalline grain structure, the intergranular boundaries of which serve as effective sinks for primary radiation defects. [ABSTRACT FROM AUTHOR]

Published

2024

8. Metal Painting by Plasma Jet.

Author

Lockwood Estrin, Francis, Hagger, Oliver S.J., Sener, M. Emre, and Caruana, Daren J.

Subjects

ATMOSPHERIC pressure plasmas, HELIUM plasmas, PLASMA jets, DIELECTRIC materials, SALTWATER solutions

Abstract

Conducting metal interconnections are essential to link electronic components or multiple circuits for electronic device fabrication. Scalable, rapid, and sustainable methods for printing adherent metal interconnections on dielectric materials are lacking, which stifles the development of new electronic consumer devices. Here a breakthrough single‐step and rapid process to deposit highly conducting metal tracks is introduced, using an atmospheric pressure plasma jet. The deposition process used a rudimentary aqueous solution of metal salts as ink, that was introduced as a mist into a helium plasma gas. The metal salt was reduced and deposited with spatiotemporal control using a plasma jet generated at radio frequency with 15 W power at room temperature and pressure. The conductive metal layers were highly adhesive on glass, ceramics, polymeric materials, even biological surfaces such as plant leaves and animal skin, depostedwith little damage to the substrate. The conductivity of deposited tracks on glass shows 50.8 ± 8.6% and 5.2 ± 1.6% of bulk silver and copper metal conductivity respectively. [ABSTRACT FROM AUTHOR]

Published

2024

9. Spatially resolved measurements of electron density of a magnetically confined split-ring resonator source.

Author

Walsten, Andrew T., Bentz, Brian Z., Youngman, Kevin, and Xu, Kunning G.

Subjects

*PLASMA resonance, *HELIUM plasmas, *ELECTRON density, *ELECTRON temperature, *PLASMA sources

Abstract

Laser-collisional induced fluorescence is used to study the plasma generated by a split-ring resonator discharge under an external cusp shaped magnetic field created by permanent magnets. The electron density and electron temperature are measured for a helium plasma at different pressures, powers, and magnet field strengths. It is found that the magnetic fields produce higher electron temperatures with peak temperatures of ∼3 eV, while the no magnet case has peak temperatures of ∼0.8 eV. Conversely, the peak electron density is obtained in the no magnet case at a value of ∼1.9 × 1011 cm−3. This indicates that the cusp-field did magnetize the electrons, but contrary to expectations, it resulted in a decrease in electron density. This is believed to be due to the magnetic field having negative effects on the resonance of the plasma source. [ABSTRACT FROM AUTHOR]

Published

2024

10. VOCs conversion in He/H2O plasma produced in a micro-capillary tube at atmospheric pressure.

Author

Bauville, G, Heninger, M, Lemaire, J, Jeanney, P, Santos Sousa, J, Pallandre, A, and Pasquiers, S

Subjects

*CYCLOTRON resonance, *VOLATILE organic compounds, *METASTABLE ions, *METASTABLE states, *HELIUM plasmas

Abstract

A non-equilibrium plasma is created in a micro-capillary quartz tube (800 µ m of internal diameter), by a DC-pulsed micro-dielectric barrier discharge (micro-DBD) and the propagation of an ionisation wave, in mixtures of He/H2O/VOC at atmospheric pressure where the studied volatile organic compounds (VOCs) are representative of molecules belonging to different chemical families: alcohols (methanol, ethanol, isopropanol, tert-butanol), ketones (acetone), nitriles (acetonitrile), and aromatic hydrocarbons (toluene). The conversion efficiency of these VOCs is studied as a function of the applied voltage on the micro-DBD (or electrical energy deposited in the plasma) and of the initial concentration of the molecules in the range from 1 ppm up to 3000 ppm (depending on the molecule), with the help of high-resolution real-time mass spectrometry Fourier transform ion cyclotron resonance associated to chemical ionisation (CI-FTICR) using H3O+ as precursor ion. A variety of by-products resulting from the conversion of VOCs are identified and quantified, emphasising that the micro-capillary plasma is able to induce a complex chemical reactivity. A qualitative analysis of the involved kinetics, based on the existing literature, reveals that helium species (ions and metastable states) and radicals coming from the dissociation of the water molecules (O and OH) are the most probable candidates to explain the formation of all compounds detected by the CI-FTICR apparatus. Quenching processes of the metastable He(23S) by the VOCs, leading to the dissociation of the molecules, are suggested to explain some of the experimental results. [ABSTRACT FROM AUTHOR]

Published

2025

11. Impact of self-sputtering in high power impulse magnetron sputtering (HiPIMS) with helium.

Author

Morel, Erwan, Rozier, Yoann, El Farsy, Abderzak, and Minea, Tiberiu

Subjects

*MAGNETRON sputtering, *HELIUM plasmas, *ELECTRON density, *PLASMA-wall interactions, *EMISSION spectroscopy, *HELIUM

Abstract

Conventional magnetron discharge is a widely used technology for many applications. In the last decade, the high current density sputtering regime has been an interesting alternative for tailoring thin film properties. In this paper, we focused on the electrical characterization of the helium magnetron plasma operated at average gas pressure (5 Pa) with a molybdenum target. Optical emission spectroscopy diagnostics also supports this study by providing information on electron density evolution. The analysis of the plasma–surface interaction zone on the target unveiled the physical mechanisms associated with the high current density range (6 A cm−2), corresponding to different discharge regimes. The self-sputtering yield plays a key role in high-power impulse magnetron sputtering discharge operated with helium. The electron density is highly dependent on the presence of a metal. [ABSTRACT FROM AUTHOR]

Published

2023

12. Effect of Helium Plasma Irradiation on Microstructures and Mechanical Properties of Tungsten.

Author

Kengesbekov, Aidar, Rakhadilov, Bauyrzhan, Satbaeva, Zarina, Kambarov, Yedilzhan, and Sonar, Tushar

Subjects

*SURFACE structure, *SURFACE roughness, *TUNGSTEN, *PLASMA temperature, *IRRADIATION, *HELIUM plasmas

Abstract

The paper presents the results of the study of tungsten surface structure modification under helium plasma irradiation. It is revealed that during irradiation of samples, surface modification in the form of relief development as a result of irradiation is observed. X‐ray phase analysis showed that no new phases of the W system were found after irradiation, only an increase in the intensity of diffraction lines was observed. There are significant differences in the microstructure of tungsten depending on the temperature of helium plasma irradiation in the above range. It is assumed that the cause of defects is the extremely low solubility of helium in tungsten. Metallographic analysis has shown that at irradiation of tungsten samples in time modes 1 and 1.5 hours, the degree of relief development is not high in comparison with the tungsten sample irradiated in the 0.5‐hour mode. The greatest increase in surface roughness of the sample irradiated for 1 hour was registered, which is associated with the formation of small cracks, bubbles, and pores in the surface layer. At the same time, in the samples irradiated for 1.5 hours, the surface of which is characterized by chaotically located protrusions and depressions of various shapes, the roughness parameter Ra was 0.0603 μm. It was found that at temperature regimes T = 1200°C and T = 1500°C, the microhardness of tungsten increases by 10% and 11%, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

13. Comparison of the scrape‐off layer two‐point model for deuterium and helium plasmas in JET ITER‐like wall low‐confinement plasma conditions.

Author

Rees, David, Sissonen, Joona, Groth, Mathias, Rikala, Vesa‐Pekka, Kumpulainen, Henri, Thomas, Beth, and Brix, Mathias

Subjects

*HELIUM plasmas, *PLASMA jets, *ION temperature, *DEUTERIUM plasma, *THOMSON scattering

Abstract

The hydrogenic two‐point model (H‐2PM), an analytical model for the scrape‐off layer that predicts a common electron and ion temperature and density along a flux tube from a target temperature and density, is adapted to a single‐species helium (He) model, preserving the 2PM assumptions and analytical nature. Across a range of densities and heating powers, the predicted Te$$ {T}_e $$ is within 20eV$$ 20\kern0.3em \mathrm{eV} $$ of upstream measurements by high‐resolution Thomson scattering (HRTS) for low‐confinement He plasmas performed in JET ITER‐like wall (JET‐ILW). For high‐recycling conditions, He‐2PM predictions of ne$$ {n}_e $$ were within 10% of the Li‐beam diagnostic measurements, excluding the near‐SOL, when assuming Zeff=1$$ {Z}_{\mathrm{eff}}=1 $$, suggesting the divertor SOL was not fully ionised in the JET‐ILW He plasmas. [ABSTRACT FROM AUTHOR]

Published

2024

14. Plasma-Chemical and Reactive Ion Etching of Gallium Arsenide in Difluorodichloromethane with Helium.

Author

Murin, D. B., Chesnokov, I. A., Gogulev, I. A., Anokhin, A. L., and Moloskin, A. E.

Subjects

*PLASMA radiation, *ION bombardment, *SEMICONDUCTOR wafers, *GALLIUM arsenide, *SURFACE cleaning, *HELIUM plasmas

Abstract

The kinetics of the interaction of high-frequency plasma of difluorodichloromethane and its mixture with helium with the surface of gallium arsenide (GaAs) is experimentally studied. It is established that in the studied range of conditions, the original difluorodichloromethane molecule completely decomposed into atomic carbon. It is confirmed that the main chemically active particles responsible for etching are reactive chlorine atoms. It is shown that the etching process occurs in the mode of an ion-stimulated chemical reaction, where the desorption of products under the influence of ion bombardment plays a significant role in cleaning the surface. The emission spectra of plasma radiation in the presence of a GaAs semiconductor wafer are analyzed. The control lines and bands are selected to control the rate of the etching process based on the emission intensity of the lines and bands of the etching products. [ABSTRACT FROM AUTHOR]

Published

2024

15. Helium Plasma Effects on Polymer Surfaces: from Plasma Parameters and Surface Properties towards Bioengineering Applications.

Author

Nastuta, Andrei Vasile, Butnaru, Maria, Cheatham, Byron, Huzum, Ramona, Tiron, Vasile, and Topala, Ionut

Subjects

*HELIUM plasmas, *PLASMA sources, *ELECTRIC discharges, *PLASMA pressure, *PLASMA jets

Abstract

Plasma treatment is necessary to optimize the performance of biomaterial surfaces. It enhances and regulates the performance of biomaterial surfaces, creating an effective interface with the human body. Plasma treatments have the ability to modify the chemical composition and physical structure of a surface while leaving its properties unaffected. They possess the ability to modify material surfaces, eliminate contaminants, conduct investigations on cancer therapy, and facilitate wound healing. The subject of study in question involves the integration of plasma science and technology with biology and medicine. Using a helium plasma jet source, applying up to 18 kV, with an average power of 10 W, polymer foils were treated for 60 s. Plasma treatment has the ability to alter the chemical composition and physical structure of a surface while maintaining its quality. This investigation involved the application of helium plasma at atmospheric pressure to polyamide 6 and polyethylene terephthalate sheets. The inquiry involves monitoring and assessing the plasma source and polymer materials, as well as analyzing the impacts of plasma therapy. Calculating the mean power of the discharge aids in assessing the economic efficacy of the plasma source. Electric discharge in helium at atmospheric pressure has beneficial effects in technology, where it increases the surface free energy of polymer materials. In biomedicine, it is used to investigate cytotoxicity and cell survival, particularly in direct blood exposure situations that can expedite coagulation. Comprehending the specific parameters that influence the plasma source in the desired manner for the intended application is of utmost importance. [ABSTRACT FROM AUTHOR]

Published

2024

16. Characteristics of Aqueous Chemical Species Generation in Plasma‐Facing Liquid Systems Using Helium Jet Plasma.

Author

Park, Joo Young, Bae, Jin Hee, and Lee, Seunghun

Subjects

*PLASMA jets, *HELIUM plasmas, *CHEMICAL species, *PLASMA flow, *IMMERSION in liquids

Abstract

Plasma‐facing liquids (PFLs) facilitate the storage of reactive O and N species (RONS), including H2O2 and NO2−, which remain in the PFL after plasma treatment, and they can continuously influence the target immersed in the liquid. However, their behaviors and levels of generation and extinction depend strongly on the plasma characteristics and liquid condition. Therefore, understanding the effects of the liquid type on the plasma discharge characteristics and the RONS generated via plasma discharge is necessary. We compared the RONS generation and storage trends of deionized H2O and a high‐conductivity PFL, RPMI 1640, which is a well‐known cell culture medium commonly used to culture mammalian cells. RPMI 1640 acted as an electrode and enhanced the plasma discharge power by supplying abundant radicals and RONS. The production of gaseous hydroxyl radicals and NO markedly increased, which facilitated H2O2 and NO2− production in the PFL for the first 200 s, and then the increase in the RONS concentration stagnated. With respect to storage, as the components within RMPI 1640 exhibited high reaction constants for their reactions with H2O2, H2O2 elimination was completed in <30 min. Unlike H2O2, the concentration of NO2− in the PFL was unchanged. [ABSTRACT FROM AUTHOR]

Published

2024

17. Improving hydrogen storage in cobalt/carbon nanotube nanocomposites using cold helium plasma irradiation.

Author

Barjasteh, Azadeh, Malmir, Maryam, Mousavi, Fariba, Alibeigi, Somayeh, and Bazvand, Fatemeh

Subjects

MULTIWALLED carbon nanotubes, HELIUM plasmas, LOW temperature plasmas, CARBON nanotubes, HYDROGEN storage

Abstract

In this article, we investigate the radiation of cold plasma composed of helium gas on the amount of hydrogen storage in cobalt/carbon nanotube nanocomposite. For this study, the solution is divided into two parts, one part of which does not receive any radiation from the plasma. For the other part, before the layers are deposited, a cold plasma consisting of helium gas is applied to the suspension consisting of multi-walled carbon nanotubes. and we irradiate cobalt salt for 30 seconds, then we address the layers by electrochemical method. The results show that plasma treatment even in a short period like 30 seconds increases the hydrogen desorption capacity by creating defects and active groups on the surface of nanotubes that are favorable for hydrogen storage. [ABSTRACT FROM AUTHOR]

Published

2024

18. Empirical analysis of a hollow cathode's intensity distribution in the vacuum ultraviolet range.

Author

Olsen, S. C., Allred, D. D., and Vanfleet, R. R.

Subjects

CATHODES, HELIUM plasmas, LIGHT sources, GLOW discharges

Abstract

Hollow cathodes are a common type of vacuum ultraviolet (VUV) light source with a wide range of design and application. We determined the VUV (58.4 nm) intensity distribution of a hollow cathode as a function of current and pressure. Our model describes the intensity distribution of a McPherson 629-like hollow cathode helium plasma within the range of 0.50–1.00 A and 0.50–1.00 Torr as a ring with a center peak. We found that for all pressures and currents considered, the ring emits more VUV light than the center peak. We also found that the center peak has a minimum VUV light emission near 0.9 Torr. [ABSTRACT FROM AUTHOR]

Published

2024

19. An opportunity for post‐harvest seafood safety: atmospheric pressure air or helium cold plasma to control Salmonella Enteritidis in sea bass.

Author

Üçok, Didem, Akan, Tamer, Kartal, Sehban, Tosun, Şehnaz Yasemin, Mol, Sühendan, Coşansu, Serap, Doğruyol, Hande, Ulusoy, Şafak, and Bostan, Kamil

Subjects

*HELIUM plasmas, *SALMONELLA enteritidis, *SEA basses, *LOW temperature plasmas, *AIR pressure, *ATMOSPHERIC pressure, *SALMONELLA typhimurium, *SALMONELLA

Abstract

Summary: Salmonella contamination of fish after harvest is a significant food safety risk. To control this risk, it was aimed to reduce Salmonella Enteritidis in sea bass by helium and air plasma. Considering that preserving the fresh properties of sea bass is important for industrial applicability, determining the sensory effects of plasma treatments was also aimed. Since air plasma would provide a cheaper and easier alternative to helium plasma, their effects were compared. Additionally, the in vitro effects of these treatments on Salmonella Enteritidis were also investigated. Air and helium plasma completely inhibited the initial load of S. Enteritidis (2.79 Log CFU) inoculated on agar surface after 10 min treatment. Then, the inoculated sea bass samples were exposed to air or helium plasma for durations ranging from 1 to 15 min. Air and helium plasma treatments for 10 min provided 0.90 log cfu g−1 and 1.13 Log CFU/g reductions, respectively, but longer treatments did not lead to further significant reductions. Sensory scores were all above 7 (good) when samples were treated with air or helium plasma for 1–10 min, but longer treatments resulted in lower scores. The reduction of S. Enteritidis and changes in sensory characteristics were interpreted together and it was concluded that 10 min of air or helium plasma provided maximum reduction without causing any significant sensory changes. Overall, the current study showed that atmospheric pressure air and helium plasmas can be useful for ensuring post‐harvest safety in the fish trade. [ABSTRACT FROM AUTHOR]

Published

2024

20. Simulation studies of tungsten impurity behaviors in helium plasma in comparison with deuterium plasma via SOLPS-ITER.

Author

Liu, Xiaoju, Gao, Shanlu, Shi, Qiqi, Ming, Tingfeng, Li, Guoqiang, and Gao, Xiang

Subjects

*DEUTERIUM plasma, *HELIUM plasmas, *STAGNATION point, *PLASMA flow, *ELECTRON density, *TUNGSTEN

Abstract

The sputtering and transport of tungsten (W) impurities in helium (He) and deuterium (D) plasma discharges are compared using the SOLPS-ITER code. To reduce the computational resources of modeling, W ions are treated using the bundled charge state model. The results show that the W erosion flux of He plasma is almost a factor of two higher than that of D plasma under the same upstream electron density and heating power due to the higher W sputtering yield in He plasma. Moreover, the W self-sputtering flux is significantly higher than the W flux sputtered by the main ions. The leakage and retention of W impurities in the divertor region is also analyzed. W ions mainly escape from the near scrape-off layer (SOL) region through the divertor entrance as the stagnation point of the average W impurity poloidal velocity is considerably closer to the target plates in the near SOL region. Furthermore, the leakage flux of W ions in He plasma is higher than that in D plasma, mainly because of the higher W sputtering level in He plasma, which results in a larger W density. W ions with low-lying charge states, mostly comprising the charge state of W10–12+, easily escape from the divertor through the near SOL flux tubes in both D and He plasmas. In addition, the effects of upstream electron density on W sputtering and retention in He and D plasma discharges are presented. [ABSTRACT FROM AUTHOR]

Published

2024

21. Cold plasma‐assisted extraction of anthocyanin from purple corncobs and its antioxidant activity.

Author

Xu, Xiaoyan, Zhang, Meng, Zhu, Guobing, Gong, Lei, Qing, Qing, Wang, Liqun, Xu, Jieting, Zhu, Jie, and Yi, Xia

Subjects

CORNCOBS, ANTHOCYANINS, PLANT cell walls, LOW temperature plasmas, HELIUM plasmas, AGRICULTURAL wastes

Abstract

In this study, a novel radio‐frequency cold plasma‐assisted extraction (CPAE) process was developed for the extraction of anthocyanins from a type of agricultural biomass waste, purple corncob. The effects of cold plasma pretreatment on anthocyanin extraction were investigated, and this process was further optimized using response surface methodology. The components of purple corncob anthocyanins (PCAs) were analyzed by super‐high performance liquid chromatography‐mass spectrum. The antioxidant activity of PCAs was evaluated through 2,2‐diphenyl‐1‐picrylhydrazyl (DPPH) and 2′‐azinobis‐(3‐ethylbenzthiazoline‐6‐sulfonate) (ABTS) scavenging capacity assays in vitro and physiological behaviors in vivo for Caenorhabditis elegans. The results showed that the optimal conditions of cold plasma pretreatment were discharge power 127 W, working pressure 150 Pa, and the treatment time 75 s. The maximum yield of PCAs was about 4.05 ± 0.05 mg/g corncob, much higher than that of the conventional solvent extraction and ultrasonic‐assisted extraction. PCAs were mainly composed of pelargonidin‐3‐galactoside (66.02 wt.%), cyanidin‐3‐galactoside (25.95 wt.%), cyanidin (8.02 wt.%), and petunidin‐3‐galactoside (0.02 wt.%). The extracted anthocyanins reflected the superior antioxidant activity. In terms of in vitro antioxidant ability, the half maximal inhibitory concentration (IC50) of PCAs for DPPH and ABTS were slightly lower than those of ascorbic acid. Meanwhile, C. elegans exhibited positive effects on several physiological behaviors by feeding PCAs, including a 29.25% increase in lifespan, and increases in antioxidant capacity, superoxide dismutase, and catalase (CAT) activity of 26.28%, 28.93%, and 22.24%, respectively. The CPAE process is therefore a highly competitive candidate for the realization of industrial PCAs extraction, combining some additional advantages of cold plasma treatment such as green process, low cost, short treatment time, and scale‐up production. Practical applications: Agricultural biomass wastes (e.g., corncob, straws, and husks) contain a large number of high value‐added natural active ingredients (e.g., polysaccharides, anthocyanins, and polyphenols). However, a highly efficient extraction of these natural active ingredients is always sought, as the protection of lignocellulosic cell walls hinders the extraction of intracellular products. In this work, the cold plasma‐assisted extraction (CPAE) process showed a comparatively higher anthocyanin yield than the conventional solvent extraction and ultrasonic‐assisted extraction processes. This was due to the fact that the high‐energy helium plasma attack readily broke down the lignocellulosic structure of the plant cell walls, resulting in the rapid release of intracellular purple corncob anthocyanins into the extraction medium. This study suggests that the CPAE process will become an emerging application for the industrial extraction of high value‐added natural active ingredients from agricultural biomass wastes. [ABSTRACT FROM AUTHOR]

Published

2024

22. Growth of fiberform nanostructures on metal surfaces by helium plasma irradiation.

Author

Kajita, Shin, Ito, Atsushi M., and Ibano, Kenzo

Subjects

*METALLIC surfaces, *HELIUM plasmas, *NANOSTRUCTURES, *GAS detectors, *IRRADIATION, *HELIUM, *TUNGSTEN, *HELIUM atom

Abstract

Helium plasma irradiation to various metals leads to peculiar morphology changes as forming fiberform nanostructures called fuzz when a certain set of conditions is satisfied. In this Tutorial, we overview experimental observations about the fuzz growth process, conditions, growth rate, etc. on tungsten (W), and fuzz growth observed on other various metals. The fuzz growth mechanism, open questions about fuzz growth, and current understandings on these issues are discussed based on simulation and theoretical works. Several applications (gas sensors and photocatalytic application) with fuzz are shown. We hope that this Tutorial will help new researchers in this field to perform experiments and simulations to reveal new perspectives of fuzz. [ABSTRACT FROM AUTHOR]

Published

2022

23. Electronically Temperature-Dependent Interplay between He and Trivacancy in Tungsten Plasma-Facing Materials.

Author

Fu, Zhao-Zhong and Pan, Bi-Cai

Subjects

*ELECTRONIC excitation, *TUNGSTEN, *ATOMS, *INHIBITORY postsynaptic potential, *HELIUM plasmas

Abstract

Both microvoids and helium (He) impurities are widely present in tungsten (W) plasma-facing materials (PFMs), where the interaction between microvoids and He atoms has led to the intriguing development of microvoids. In this paper, we comprehensively investigated the interaction between He atoms and trivacancy (V3), a fundamental microvoid in W-PFMs, at the level of tight-binding theory. Our study showed that He atoms can catalyze the decomposition of the original V3 or facilitate its transformation into another V3 variant. We propose that a He atom near the V3 defect induces significant changes in the distribution of d-electron charges within the W atoms lining the inner wall of the V3 defect, making the W atom nearest to this He atom cationic and the other W atoms anionic. The attractive interaction between them promotes the decomposition and deformation of V3. As electronic excitation increases, the ionization of W atoms on the V3 wall gradually intensifies, thereby enhancing the cationic characteristics of the W atoms closest to the He atom. This process also prompts other W atoms to shift from anions to cations, leading to a transition in the electrostatic interactions between them from attraction to repulsion. This transformation, driven by electronic excitation, plays a significant inhibitory role in the decomposition and deformation of V3. [ABSTRACT FROM AUTHOR]

Published

2024

24. Simulation of the impact of humidity on the species generated by a one-dimensional discharge of helium gas.

Author

Soltani, Zahra, Mehrabifard, Ramin, Rezaei, Fatemeh, Hatami, Mohammad Mohsen, and Soltani, Hamed

Subjects

*ELECTRIC discharges, *HIGH-frequency discharges, *HELIUM plasmas, *GLOW discharges, *PLASMA materials processing, *REACTIVE oxygen species, *HUMIDITY

Abstract

Dielectric barrier discharge (DBD) plasma has several applications in different fields. One of these fundamental applications is medical usages, where various methods are employed to improve the plasma treatment process. The combination of different gases is one of the important strategies to improve the performance of plasma in treatment. In this paper, the optimized plasma parameters for one-dimensional radiofrequency discharge produced at low pressures in a helium gas combination is studied. In this research, the optimal combination of H2O and He is identified to attain the highest amount of reactive oxygen species (ROS). Considered mixture are 5, 10, 15 and 20 precent of H2O for one dimensional helium gas discharge. The results show that the parameters of the output plasma are highly dependent on the composition of the input gases. It is found that the greatest concentrations of H+, H+, Hes (excited helium), and OH densities are observed when the H2O percentage was at 10%. Moreover, the density distributions of various species and the temperatures of electrons are numerically calculated during the electrical discharge process. These findings provide useful knowledge on how to optimize plasma parameters for biomedical applications, which may lead to improved treatment results in several therapeutic areas. [ABSTRACT FROM AUTHOR]

Published

2024

25. Colorimetric Readout Based Photoionization Detector for Gas Chromatographs.

Author

Mao, Jingqin, Liu, Longze, Atwa, Yahya, Hou, Junming, and Shakeel, Hamza

Subjects

*GAS detectors, *PHOTOIONIZATION, *LUMINESCENCE, *GAS chromatography, *HELIUM plasmas, *COLUMN chromatography, *ACETONE

Abstract

This paper presents a new scheme for readout of a photoionization detector (PID) that utilizes the ionization luminescence of target gases in helium plasma to generate an output signal. Our signal readout method is based on processing the recorded video and correlating the light peak intensity with the sample injection time and concentration. We successfully demonstrated the feasibility of a colorimetric readout‐based photoionization detector coupled with a gas chromatography column by detecting a mixture of non‐polar compounds (alkanes) and two polar compounds (acetone and ethanol). The detection limit for our first‐generation device was calculated to be ~118 ng for acetone and around 26 ng for ethanol. © 2024 Institute of Electrical Engineer of Japan and Wiley Periodicals LLC. [ABSTRACT FROM AUTHOR]

Published

2024

26. Helium atom embedded in non‐ideal classical plasmas: Doubly excited singlet S states.

Author

Das, Netai, Ghoshal, Arijit, and Ho, Yew Kam

Subjects

*HELIUM atom, *DEBYE length, *EXCITED states, *PSEUDOPOTENTIAL method, *THRESHOLD energy, *PLASMA potentials, *HELIUM plasmas

Abstract

The influence of the non‐ideality (NI) of the classical plasmas on the doubly excited singlet S states of the helium atom (He) embedded in the plasma has been investigated theoretically. A pseudopotential containing the Debye length and the non‐ideality parameter (NIP) as its characteristics is used to represent the screened interaction potentials in the plasma. Using a large wavefunction within the framework of the stabilization method, it has been possible to recognize six doubly excited singlet S states (five lying below the He+(2S) excitation threshold and one lying below the He+(3S) excitation threshold) for the plasma‐free case. The energies and the autoionization life‐times of those states are computed by fitting the density of states to the Lorentzian form. Convergence of the computed results is corroborated by increasing the number of terms in the employed wavefunction. For the plasma‐free case, these results are in excellent agreement with the established results in the literature. A comprehensive analysis has been made on changes induced on those doubly excited states by varying NI over a wide range. It has been observed that the energies of the states gradually approach the corresponding threshold energies with the increasing NI of the plasma, whereas the change in the life‐times (alternatively the widths of the states) of the states shows distinctive features depending on the angular momentum of an individual electron. [ABSTRACT FROM AUTHOR]

Published

2024

27. Modeling of the particle fluxes of a helium plasma jet onto water surface.

Author

Liu, Yifan, Wang, Sui, Peng, Yan, Peng, Wenyi, Liu, Dingxin, and Fu, Feng

Subjects

*ATMOSPHERIC pressure plasmas, *WATER jets, *BOUNDARY layer (Aerodynamics), *GAS distribution, *GLOW discharges, *HELIUM plasmas, *PLASMA jets

Abstract

The interaction between an atmospheric pressure plasma jet (APPJ) and an aqueous solution has great application prospects in biomedicine and many other fields. Reactive species adjacent to a water surface is critical to the activation of APPJ-treated water, which is affected by both the water evaporation and the admixture of ambient air. In this paper, taking He APPJ as an example, a two-dimensional (2D) cylindrically symmetric fluid model is developed to obtain the spatial distributions of gas components before discharging, and a series of global models are developed for the discharge in the boundary gas layer adjacent to the water surface. The interfacial distributions of reactive species and their fluxes onto the water surface are quantified. It is found that the electron density is 1016–1017 m−3 and it shows an annular distribution in the boundary gas layer. The density distributions of most reactive species there reveal ring-like shapes as well. The dominant cation and anion in such a boundary layer are H3O+ and OH−, respectively. The most abundant metastable is O2(a1Δ), the most abundant reactive oxygen species are H2O2 and OH, and the most abundant reactive nitrogen species are NO and HNO2. The species of H2O2, OH, HO2, and HNO2 are reportedly to have significant biological effects, and in our simulation, their fluxes onto the water surface are remarkable, higher than 1017 m−2 s−1. In addition, the effects of radial gas velocity and water evaporation on the particle flux distributions are also revealed. [ABSTRACT FROM AUTHOR]

Published

2024

28. Experimental investigation of electrostatic capture of 1+ ions in charge breeder electron cyclotron resonance ion source plasma.

Author

Tarvainen, O., Angot, J., Chauveau, P., Galatà, A., and Thuillier, T.

Subjects

*ION sources, *ELECTRON cyclotron resonance sources, *ION traps, *HELIUM plasmas, *PLASMA sources, *ION-ion collisions

Abstract

We present comprehensive experimental data demonstrating that the capture process of the 1 + ions in charge breeder electron cyclotron resonance ion sources (ECRIS) is dominated by electrostatic deceleration by the ambipolar plasma potential, not by cumulative small-angle scattering of the incident ions in ion–ion collisions as postulated previously. To achieve this we varied the plasma potential of an ECRIS charge breeder by adjusting the microwave power applied to sustain the helium discharge and measured the corresponding shift in the optimum injection energy of the 1 + ions. The experiment was repeated with sodium, potassium, and cesium ions. It is shown that the optimum injection energy does not depend on the incident ion mass, which contradicts the collisional drag model. Conversely, the optimum injection energy (in eV) shifts in unison with the plasma potential (in V), which provides strong evidence for the electrostatic deceleration hypothesis. [ABSTRACT FROM AUTHOR]

Published

2024

29. Influence of Microsecond Pulse Helium Plasma Flow on the Surface Morphology and Crystal Structure of the Photovoltaic Converters Based on CdS/CdTe.

Author

Khrypunov, G. S., Harchenko, M. M., Meriuts, A. V., Carlin, J. F., Makhlai, V. A., Herashchenko, S. S., Abashin, S. L., Surovitskiy, S. V., Pudov, A. O., and Dobrozhan, A. I.

Subjects

CRYSTAL morphology, PLASMA flow, CRYSTAL structure, SURFACE morphology, CRYSTAL surfaces, HELIUM plasmas, IRRADIATION, PLASMA jets

Abstract

The influence of pulsed helium plasma irradiation, with a 10 μs duration and a surface energy load of 0.2 MJ m-2, on the elemental and phase composition, surface morphology and crystal structure of thin-film heterosystems based on CdS/CdTe was studied. The cadmium sulphide and cadmium telluride layers were deposited by condensation via a hot wall method onto a glass substrate covered with an FTO layer. It was found that after one pulse, the device structure remains in working condition. An increase in the irradiation dose leads to surface sputtering, the formation of through pores 0.5 – 2 μm in size, and a microcracks network with two characteristic scales. One crack network is formed in the glass substrate, and the second network is formed with cracks in the CdTe film. It is shown that the thermal effect of plasma stimulates the diffusion of sulphur; as a result, the proportion of CdTe1-xSx solid solutions formed in the process of obtaining the CdS/CdTe heterosystem increases. In addition, the sulphur content increases in these solid solutions, which leads to their decomposition with the separation of the CdS1-yTey solid solution phase. These solid solutions migrate to the CdTe surface through cracks and are observed as separate crystals. [ABSTRACT FROM AUTHOR]

Published

2024

30. How does atmospheric pressure cold helium plasma affect the biomechanical behaviour on alkali-lesioned corneas?

Author

Neri, Simona, Mascolini, Maria Vittoria, Peruffo, Antonella, Todros, Silvia, Zuin, Matteo, Cordaro, Luigi, Martines, Emilio, Contiero, Barbara, Carniel, Emanuele Luigi, Iacopetti, Ilaria, Patruno, Marco, Fontanella, Chiara Giulia, and Perazzi, Anna

Subjects

*HELIUM plasmas, *CORNEA, *AMNION, *RELAXATION phenomena, CORNEAL ulcer

Abstract

Background: Melting corneal ulcers are a serious condition that affects a great number of animals and people around the world and it is characterised by a progressive weakening of the tissue leading to possible severe ophthalmic complications, such as visual impairment or blindness. This disease is routinely treated with medical therapy and keratoplasty, and recently also with alternative regenerative therapies, such as cross-linking, amniotic membrane transplant, and laser. Plasma medicine is another recent example of regenerative treatment that showed promising results in reducing the microbial load of corneal tissue together with maintaining its cellular vitality. Since the effect of helium plasma application on corneal mechanical viscoelasticity has not yet been investigated, the aim of this study is first to evaluate it on ex vivo porcine corneas for different exposition times and then to compare the results with previous data on cross-linking treatment. Results: 94 ex vivo porcine corneas divided into 16 populations (healthy or injured, fresh or cultured and treated or not with plasma or cross-linking) were analysed. For each population, a biomechanical analysis was performed by uniaxial stress-relaxation tests, and a statistical analysis was carried out considering the characteristic mechanical parameters. In terms of equilibrium normalised stress, no statistically significant difference resulted when the healthy corneas were compared with lesioned plasma-treated ones, independently of treatment time, contrary to what was obtained about the cross-linking treated corneas which exhibited more intense relaxation phenomena. Conclusions: In this study, the influence of the Helium plasma treatment was observed on the viscoelasticity of porcine corneas ex vivo, by restoring in lesioned tissue a degree of relaxation similar to the one of the native tissue, even after only 2 min of application. Therefore, the obtained results suggest that plasma treatment is a promising new regenerative ophthalmic therapy for melting corneal ulcers, laying the groundwork for further studies to correlate the mechanical findings with corneal histology and ultrastructural anatomy after plasma treatment. [ABSTRACT FROM AUTHOR]

Published

2024

31. Ab initio investigation of potential energy curves of He2, He2+, and extrapolation by the machine learning method.

Author

Xu, Shaofeng, Lu, Aijiang, Zhong, Xiaoxia, Guo, Ying, and Shi, Jianjun

Subjects

*POTENTIAL energy, *MACHINE learning, *EXCITED states, *EXTRAPOLATION, *HELIUM plasmas, *DIATOMIC molecules

Abstract

Diatomic molecules He2+$$ \mathrm{H}{\mathrm{e}}_2^{+} $$, He2$$ \mathrm{H}{\mathrm{e}}_2 $$ are common compositions in plasmas using the helium as the working gas, and play key roles in quenching O2 and N2. However, the potential energy curve (PEC) of the first state He2a3Σu+$$ \mathrm{H}{\mathrm{e}}_2\left({a}^3{\Sigma}_u^{+}\right) $$ obtained at the CASSCF level of theory is not accuracy and data of higher excited states of He2+$$ \mathrm{H}{\mathrm{e}}_2^{+} $$ are lacking. Here, we calculated PECs of four excited states of He2$$ \mathrm{H}{\mathrm{e}}_2 $$ and nine lowest electronic states of He2+$$ \mathrm{H}{\mathrm{e}}_2^{+} $$ by employing CASSCF+MRCI/Aug‐cc‐pV5Z and CCSD(T)/Aug‐cc‐pV5Z level of theory with sample internuclear distance interval of 0.005 Å. PECs were extrapolated to the complete basis sets. There are double local maxima in PECs of three excited states He2+B2Σu+$$ \mathrm{H}{\mathrm{e}}_2^{+}\left({B}^2{\Sigma}_u^{+}\right) $$, He2+C2Πu$$ \mathrm{H}{\mathrm{e}}_2^{+}\left({C}^2{\Pi}_u\right) $$, He2+D2Πg$$ \mathrm{H}{\mathrm{e}}_2^{+}\left({D}^2{\Pi}_g\right) $$. The machine learning method based on the Gaussian process was used to interpolate and extrapolate the PECs, and then vibrational wave functions are solved numerically. This ab initio investigation provided rotational‐vibrational constants and new data for experimental research in the future. [ABSTRACT FROM AUTHOR]

Published

2024

32. Effect of Intermittent Low-Pressure Radiofrequency Helium Cold Plasma Treatments on Rice Gelatinization, Fatty Acid, and Hygroscopicity.

Author

Cao, Ziyi, Li, Xingjun, Song, Hongdong, Jie, Yu, and Liu, Chang

Subjects

RICE flour, LOW temperature plasmas, HELIUM plasmas, GELATION, FATTY acids, STARCH, RICE, FERULIC acid

Abstract

To establish the safe and reproducible effects of cold plasma (CP) technology on food products, this study evaluated the gelatinization parameters, fatty acid profile, and hygroscopic properties of rice grains repeatedly treated with low-pressure radiofrequency (RF) helium CP (13.56 MHz, 140 Pa, 120 W-20s, 0–4 times, and 300 g sample). Compared with the untreated (zero times) sample, with an increase in CP treatment times from one to four on rice, the water contact angle and cooking time decreased, while the water absorption rate and freshness index increased, and the pH value remained unchanged. CP repeating treatments essentially had no effect on the gelatinization enthalpy, but significantly increased the peak temperature of gelatinization. From the pasting profile of rice that has been repeatedly CP treated, the peak, breakdown, and setback viscosities in flour paste decreased. CP repeating treatments on rice did not change the short-range molecular order of starch. Compared with the untreated sample, the first helium CP treatment maintained the content of C18:1n9c, C18:2n6c, and C18:3n3, but the second to fourth CP treatment significantly decreased contents of these fatty acids (FAs) as the C18:0 content increased. The first three CP treatments can increase the water and sucrose solvent retention capacity in rice flours. CP repeatedly treated rice first exhibits the similar monolayer water content and solid surface area of water sorption. Principal component analysis shows that contact angle, pasting parameters, and fatty acid profile in milled rice are quite sensitive to CP treatment. Results support that the effect of low-pressure RF 120W helium CP treatment 20 s on rice grains is perdurable, and the improvement of CP intermittent treatments on rice cooking and pasting properties is an added benefit, and the hygroscopic properties of rice was kept. [ABSTRACT FROM AUTHOR]

Published

2024

33. Laser temperature programmed desorption: A flexible technique to study ion-surface interaction.

Author

Minissale, M., Dunand, A., Hiret, P., Faure, J.-B., Grisolia, C., Angot, T., Gallais, L., and Bisson, R.

Subjects

*AUGER electron spectroscopy, *DESORPTION, *FUSION reactors, *NUCLEAR fusion, *HYDROGEN isotopes, *ELECTRON diffraction, *MATRIX-assisted laser desorption-ionization, *HELIUM plasmas

Abstract

Understanding the physical–chemical processes ruling the interaction of particles (atoms, molecules, and ions) with surfaces is fundamental in several research fields, such as heterogeneous catalysis, astrochemistry, and nuclear fusion. In particular, the interaction of hydrogen isotopes with plasma facing materials represents a high-priority research task in the fusion community. Such studies are essential to ensure the successful operation of experimental fusion reactors, such as the tokamak ITER. In this work, we present a surface science apparatus developed to study ion-surface interaction in fusion relevant systems. It combines laser-based techniques with contaminant-free ion/molecular beams, mass spectrometry, and surface science tools such as low-energy electron diffraction and Auger electron spectroscopy. It allows to cover a wide range of sample temperatures, from 130 to 2300 K, by changing the heating rate of samples from 0.1 to 135 K/s and maintaining the linearity of the heating ramps, a powerful feature to gain insight on adsorption, absorption, and desorption mechanisms. Experimental calibration and performance are presented in detail. Moreover, to provide a factual overview of the experimental capabilities, we focus on two different applications: the protocol used to clean a W(110) single crystal sample and the development of laser temperature programmed desorption to study helium retention in tungsten. [ABSTRACT FROM AUTHOR]

Published

2024

34. On the Ionization Energy of the Atomic Gold Ion Au2+.

Author

Boltnev, R. E., Karabulin, A. V., Krushinskaya, I. N., Pelmenev, A. A., and Matyushenko, V. I.

Subjects

*NUCLEAR energy, *IONIZATION energy, *IONS, *LASER beams, *LUMINESCENCE measurement, *HELIUM plasmas

Abstract

An analysis of the luminescence spectra of plasma formed during laser ablation of a gold target immersed in superfluid helium at a laser radiation power density below the breakdown threshold of liquid helium showed that the ionization energy of the Au2+ ion should be no lower than 34 eV. [ABSTRACT FROM AUTHOR]

Published

2024

35. On the Ionization Energy of the Atomic Gold Ion Au2+.

Author

Boltnev, R. E., Karabulin, A. V., Krushinskaya, I. N., Pelmenev, A. A., and Matyushenko, V. I.

Subjects

NUCLEAR energy, IONIZATION energy, IONS, LASER beams, LUMINESCENCE measurement, HELIUM plasmas

Abstract

An analysis of the luminescence spectra of plasma formed during laser ablation of a gold target immersed in superfluid helium at a laser radiation power density below the breakdown threshold of liquid helium showed that the ionization energy of the Au2+ ion should be no lower than 34 eV. [ABSTRACT FROM AUTHOR]

Published

2024

36. The production of OH in a nanosecond pulsed helium plasma jet impinging on water, saline, or pigskin.

Author

Meimei Lai, Shutong Song, Oshin, Edwin, Potter, Lucas, Lai, Nicola, and Chunqi Jiang

Subjects

*PLASMA jets, *WATER jets, *HELIUM plasmas, *BIOMATERIALS, *NON-thermal plasmas, *LASER-induced fluorescence, *PROTON-proton interactions

Abstract

Applications of plasma-induced biological effects via reactive oxygen and nitrogen species (RONS) make the non-thermal atmospheric-pressure plasma jets an appealing tool in biomedical fields. The presence of biological materials, especially as part of the electrode circuit, may change the plasma properties and impact on the production of RONS at the plasma-biomaterial interface. Effects of biomaterials on the production of hydroxyl radicals (OH) in a nanosecond pulsed, atmospheric-pressure plasma jet were investigated using a needle-to-plate electrode configuration with water, phosphate-buffered saline (PBS), or pigskin covering the ground plate. Driven by 200 ns, 7 kV pulses at 1 kHz, a helium plasma jet was generated between the hollow needle electrode and the biomaterial. Temporally resolved UV-visible imaging showed that the use of pigskin slowed down the streamer head propagation, whereas a more pronounced surface ionization wave was developed on the surface when water was used. The highest OH(A-X) emission above the biomaterial surface was observed using the PBS-covered electrode plate comparing to water or pigskin. Spatiotemporally resolved laser-induced fluorescence (LIF) showed that more OH was produced in the region near the needle electrode for both water and PBS, and the use of pigskin resulted in least OH production overall. In addition, measurements of H2O2 production in the liquid were used to determine the OH concentration in the vicinity of the biomaterial and agreed well with the relative OH-LIF measurements obtained at the gas-liquid interface for water and PBS. [ABSTRACT FROM AUTHOR]

Published

2022

37. Fiber-form nanostructured tungsten formation by helium arc discharge plasma irradiation under a gas pressure of 5 kPa.

Author

Kikuchi, Y., Aota, T., Kadowaki, K., Tajima, M., Maenaka, S., Fujita, K., and Takamura, S.

Subjects

*ELECTRIC arc, *PLASMA arcs, *PLASMA flow, *HELIUM plasmas, *PLASMA gases, *ION energy

Abstract

Fiber-form nanostructured tungsten (W) formation was successfully demonstrated using a helium (He) arc discharge plasma generated at a gas pressure of 5 kPa. The W substrate was exposed to the He arc discharge plasma at a surface temperature of about 1000 °C. A bias voltage, Vb, was applied between the W substrate and the vacuum chamber to control the incident He ion energy, Ei. Scanning electron microscope (SEM) observations showed that the W surface was slightly roughened, but no fiber-form nanostructure was formed at a Vb of −22 V. On the other hand, fiber-form nanostructure growth was observed at a Vb of −112 V. Furthermore, cross-sectional SEM observations revealed the presence of He bubbles inside the W fibers and the sub-surface layer of the W substrate. As collisions between ions and neutrals in the sheath cannot be ignored at 5 kPa, a theoretical evaluation of Ei distribution was performed using the collisional sheath model. Furthermore, an experimental evaluation of Ei using the sputtering yield of carbon substrates by He arc discharge plasma irradiation was carried out, and then Ei was obtained to be 40–50 eV for Vb = −112 V. Therefore, the distribution of Ei at Vb = −112 V is considered to contain more than 20 eV, which is necessary for the growth of fiber-form nanostructured W found in conventional low-gas pressure plasma irradiation experiments. [ABSTRACT FROM AUTHOR]

Published

2022

38. Deciphering the influence of high-flux helium plasma exposure on tungsten nanostructure growth using real-time, in situ spectroscopic ellipsometry.

Author

Kolasinski, Robert D., Wong, Chun-Shang, Engel, Aaron, Whaley, Josh A., Allen, Frances I., and Buchenauer, Dean A.

Subjects

*ELLIPSOMETRY, *HEAT resistant alloys, *FIELD ion microscopy, *TUNGSTEN, *HELIUM plasmas, *ION energy

Abstract

In situ analysis of surfaces during high-flux plasma exposure represents a long-standing challenge in the study of plasma–material interactions. While post-mortem microscopy can provide a detailed picture of structural and compositional changes, in situ techniques can capture the dynamic evolution of the surface. In this study, we demonstrate how spectroscopic ellipsometry can be applied to the real-time characterization of W nanostructure (also known as "fuzz") growth during exposure to low temperature, high-flux He plasmas. Strikingly, over a wide range of sample temperatures and helium fluences, the measured ellipsometric parameters (Ψ , Δ) collapse onto a single curve that can be directly correlated with surface morphologies characterized by ex situ helium ion microscopy. The initial variation in the (Ψ , Δ) parameters appears to be governed by small changes in surface roughness (<50 nm) produced by helium bubble nucleation and growth, followed by the emergence of 50 nm diameter W tendrils. This basic behavior appears to be reproducible over a wide parameter space, indicating that the spectroscopic ellipsometry may be of general practical use as a diagnostic to study surface morphologies produced by high-flux He implantation in refractory metals. An advantage of the methods outlined here is that they are applicable at low incident ion energies, even below the sputtering threshold. As an example of this application, we apply in situ ellipsometry to examine how W fuzz growth is affected both by varying ion energy and the temperature of the surface. [ABSTRACT FROM AUTHOR]

Published

2022

39. Comparative study on atmospheric-pressure helium plasma jets driven by pulsed voltage with different polarity.

Author

Jiang, Yuanyuan, Wang, Yanhui, Zhang, Jiao, Cong, Shiyuan, and Wang, Dezhen

Subjects

*PLASMA jets, *ATMOSPHERIC pressure, *VOLTAGE, *HELIUM plasmas, *ELECTRIC fields, *COMPARATIVE studies

Abstract

A 2D axisymmetric study of the atmospheric pressure plasma jets driven by a trapezoidal pulse voltage with different polarities is performed in this work. The basic properties of the plasma jet in three stages, including the first discharge, the secondary discharge, and the afterglow of the plasma jet, are studied, with emphasis on the influence of voltage polarity on the secondary discharge and the afterglow. For the positive pulse voltage, the plasma jet propagates in the form of a bullet during the first stage. At the falling edge of the pulse, a new ionization wave resulting from the secondary discharge is formed and propagates forward along the preceding jet path in a continuous mode, resulting in a mixing jet propagation mode with the primary bullet and the luminous channel coexist. The plasma jet is finally converted to the continuous mode at the afterglow stage. Meanwhile, the first bullet almost stops propagating after the secondary discharge is ignited due to the rapid reduction of the electric field in the bullet head. In contrast, in the case of negative pulse voltage, a diffusive arrow-like plasma plume is observed during the first stage. The secondary discharge ignition does not completely change the direction of the electric field in the first ionization head and inhibits the propagation of the primary plasma jet. The dominant physics mechanisms associated with these observations are analyzed and discussed. In addition, the dependence of the reactive species on the secondary discharge under different pulse polarities is also compared. [ABSTRACT FROM AUTHOR]

Published

2021

40. Low onset potential for oxygen evolution reaction on hematite electrodes processed with He plasma irradiation.

Author

Kajita, Shin and Bieberle-Hütter, Anja

Subjects

*OXYGEN evolution reactions, *IRRADIATION, *ELECTRODE reactions, *HELIUM plasmas, *PLASMA materials processing, *STANDARD hydrogen electrode, *IRON, *PHOTOELECTROCHEMISTRY, *PHOTOELECTROCHEMICAL cells

Abstract

In this study, we investigated the effects of helium (He) plasma irradiation and thermal treatment on the morphology, the surface characteristics, and the photoelectrochemical performance of bulk iron (Fe) sheets. After processing, all samples consisted mainly of an α -Fe 2 O 3 surface. Helium plasma irradiation resulted in a cathodic shift in the onset potential of the photocurrent from 1.16 V RHE (no pretreatment) to 0.57 V RHE (plasma exposure at 660 ° C), where V RHE represents the potential versus reversible hydrogen electrode (RHE). An increase in the surface roughness and a smaller amount of hydroxyl or oxygen vacancies at the surface after photoelectrochemical measurement are related to the decrease of the onset potential. The results show that He plasma irradiation does not only modify the surface morphology, but also affects the functional properties of the materials. • The photoelectrochemical performance of α -Fe 2 O 3 is investigated. • Helium plasma irradiation resulted in a cathodic shift in the onset potential. • The onset potential shifted from 1.16 to 0.57 V RHE. • A small amount of hydroxyl or oxygen vacancies are likely to be the most influential. [ABSTRACT FROM AUTHOR]

Published

2024

41. High time resolution diagnosis of electron density in helium plasma jets with impurity gas.

Author

Li, Xu, Wang, Lanping, Nie, Lanlan, and Lu, Xinpei

Subjects

*PLASMA jets, *ELECTRON density, *HELIUM plasmas, *PLASMA density, *NITROGEN plasmas, *ATMOSPHERIC pressure plasmas, *MICROWAVE scattering

Abstract

Atmospheric pressure helium plasma jets are widely used in biomedical applications. Researchers normally introduce small amounts of nitrogen and oxygen (0.2–1.0%) into helium to enhance the electron density and electron energy, thus increasing the concentration of active species in plasma. To further explore why the combination of impurity gases N2/O2 leads to an increase in the electron density from the discharge mechanism, we used a microwave Rayleigh scattering method with excellent time-varying characteristics to monitor the temporal electron density changes when different concentrations of N2/O2 were mixed. The research revealed that even trace amounts of N2/O2 (0.2%) can increase the peak electron density, with this effect being more pronounced when N2 is added, increasing from 3.3 × 1019 to 4.6 × 1019 m−3 in pure helium. As the concentration increases, the introduction of O2 leads to a rapid decrease in the electron density. When 1.0% oxygen is mixed, the electron density decreases from 3.3 × 1019 to 2.4 × 1019 m−3. However, the situation is different when N2 is added, at 0.5% proportion of nitrogen, the electron density increases to its maximum at 6.5 × 1019 m−3. These effects are due to the electronegativity of the oxygen-containing particles or the Penning ionization related to excited nitrogen species. [ABSTRACT FROM AUTHOR]

Published

2024

42. Influence of operating conditions on electron density in atmospheric pressure helium plasma jets.

Author

Xu, Wenwen, Lu, Yonghang, Yue, Xiaofeng, Liu, Xiaoping, and Wu, Zhengwei

Subjects

*PLASMA jets, *ELECTRON density, *HELIUM plasmas, *ATMOSPHERIC density, *PLASMA pressure, *ATMOSPHERIC pressure

Abstract

In recent years, atmospheric-pressure plasma jets have emerged as valuable tools in many application areas, including material modification, environmental remediation and biomedicine. Understanding the discharge characteristics of these plasma jets under various operating conditions is crucial for optimizing process outcomes. This paper presents a two-dimensional fluid model for numerical simulation to study the variation in electron density within an atmospheric-pressure helium plasma jet under different operating conditions. The investigated parameters include helium gas flow rate, voltage amplitude, needle-to-ring discharge gap, and relative permittivity of the dielectric tube. The results reveal that the peak electric field and electron density initially occur at the wall of the dielectric tube and subsequently shift towards the head of the propagating jet. Gas flow rate has minimal impact on the electron density throughout the plasma jet, whereas increasing the needle-to-ring discharge gap significantly decreases the average electron density within the jet. In addition, an increase in the voltage amplitude and the relative permittivity of the dielectric tube enhances the electric field within the discharge space, thereby increasing the electron density in the plasma jet. These findings underscore the importance of understanding the correlation between electron density and operating conditions to precisely control plasma jets and enhance material treatment effectiveness for specific applications. [ABSTRACT FROM AUTHOR]

Published

2024

43. Transverse magnetic field effects on the high-voltage pulsed discharge plasma in helium.

Author

Chen, C., Rabadanov, K. M., Ashurbekov, N. A., Yuan, C., and Shakhrudinov, A. M.

Subjects

*MAGNETIC field effects, *PLASMA flow, *HELIUM plasmas, *MAGNETIC fields, *TWO-dimensional models

Abstract

This study investigates the effect of a transverse magnetic field on high-voltage pulsed discharge in helium at a pressure of 30 Torr. A simple two-dimensional fluid model that describes the high-voltage pulsed discharge in helium in a transverse weak magnetic field (B  = 0.4 T) is presented, which uses an empirical relation to account for the magnetic field. The results of using the empirical relation for the effective field agree well with the experimental results. The dynamics of discharge development in the presence of the magnetic field is also investigated. The magnetic field does not significantly affect the gas-discharge development dynamics in helium at a pressure of 30 Torr. [ABSTRACT FROM AUTHOR]

Published

2024

44. Dynamics of the plasma induced by laser on a cryogenically cooled aluminum target for application in space propulsion.

Author

Robledo-Martinez, A., Sobral, H., and Garcia-Villarreal, L. A.

Subjects

*LASER plasmas, *SPACE flight propulsion systems, *PLASMA dynamics, *LASER-induced breakdown spectroscopy, *ROCKET fuel, *ALUMINUM, *HELIUM plasmas

Abstract

In this work, we investigate the properties of the plasma induced by focusing a high-power laser beam on an aluminum target that was cooled by a helium refrigerator from room temperature down to 20 K. Fast, streak photographs of the plasma were taken at different temperatures and laser energies. From the images obtained, position-vs-time plots were made for each experiment, and from them, the speed was calculated. Additionally, narrowband interference filters were employed to image the dynamics of ions and neutrals separately. It was found that the plasma plume has two distinct speeds: that of its center and that of the outer edge. For unfiltered images, the former has values within the interval 6.2 to 9.1 km/s, while the latter can reach speeds of the order of hundreds of km/s. It was found that the plume of a target cooled to 20 K has a length that is 8%–12% less than the corresponding size at room temperature. Chilling the target did not seem to affect significantly either the plume's speed of expansion or the size of the crater produced. Lower bounds were estimated for the momentum imparted to the ejecta and the specific impulse. The latter can reach a 920-s level, nearly twice as much the amount obtained with chemical rocket fuel. [ABSTRACT FROM AUTHOR]

Published

2024

45. Temporal evolution of the light emitted by a thin, laser-ionized plasma source.

Author

Lee, Valentina, Ariniello, Robert, Doss, Christopher, Wolfinger, Kathryn, Stoltz, Peter, Hansel, Claire, Gessner, Spencer, Cary, John, and Litos, Michael

Subjects

*PLASMA sources, *LASER plasmas, *HELIUM plasmas, *PLASMA density, *PLASMA temperature, *PLASMA dynamics

Abstract

We present an experimental and simulation-based investigation of the temporal evolution of light emission from a thin, laser-ionized helium plasma source. We demonstrate an analytic model to calculate the approximate scaling of the time-integrated, on-axis light emission with the initial plasma density and temperature, supported by the experiment, which enhances the understanding of plasma light measurement for plasma wakefield accelerator (PWFA) plasma sources. Our model simulates the plasma density and temperature using a split-step Fourier code and a particle-in-cell code. A fluid simulation is then used to model the plasma and neutral density, and the electron temperature as a function of time and position. We then show the numerical results of the space-and-time-resolved light emission and that collisional excitation is the dominant source of light emission. We validate our model by measuring the light emitted by a laser-ionized plasma using a novel statistical method capable of resolving the nanosecond-scale temporal dynamics of the plasma light using a cost-effective camera with microsecond-scale timing jitter. This method is ideal for deployment in the high radiation environment of a particle accelerator that precludes the use of expensive nanosecond-gated cameras. Our results show that our models can effectively simulate the dynamics of a thin, laser-ionized plasma source. In addition, this work provides a detailed understanding of the plasma light measurement, which is one of the few diagnostic signals available for the direct measurement of PWFA plasma sources. [ABSTRACT FROM AUTHOR]

Published

2024

46. Plasma‐Driven Synthesis of Self‐Supported Nickel‐Iron Nanostructures for Water Electrolysis.

Author

Ranade, Ameya, Lao, Mengmeng, Timmer, Remco H.M., Zoethout, Erwin, van Eck, Hans J.N., and Tsampas, Mihalis N.

Subjects

WATER electrolysis, HYDROGEN evolution reactions, OXYGEN evolution reactions, HELIUM plasmas, FOAM, NANOSTRUCTURES, ION-permeable membranes, ENERGY conversion

Abstract

Nickel‐based electrocatalysts are deemed as promising low‐cost, earth‐abundant materials in the development of the next‐generation alkaline and anion exchange membrane water electrolyzers. Herein, a plasma‐processing technique is presented for fabricating self‐supported nanostructures from planar NiFe substrates and its performance for water splitting reactions. Irradiating the samples with helium plasma results in the formation of nano‐tendrils, which are affixed to the metallic substrate. This unique design not only enhances charge and mass transport, but also increases the electrochemical surface area by 3 to4 times, as compared to the unmodified/planar surfaces. For the benchmark 10 mAcm−2geo current density, the nanostructured electrodes demonstrate overpotentials of 330 and 354 mV for oxygen evolution reaction and hydrogen evolution reaction respectively in 1 M‐ KOH. Moving forward, application of this technique can be extended for fabricating self‐supported 3D substrates (e.g., foams, felts, perforated sheets), all of which find practical applications in energy conversion and storage devices. [ABSTRACT FROM AUTHOR]

Published

2023

47. Calibration of Imaging Plates for Detecting Charged Particles.

Author

Khurchiev, A. O., Panyushkin, V. A., Skoblyakov, A. V., Kantsyrev, A. V., Golubev, A. A., Gavrilin, R. O., Bogdanov, A. V., Ladygina, E. M., and Vysotskii, S. A.

Subjects

*PARTICLE detectors, *ELECTROMAGNETIC noise, *MAGNETIC spectrometer, *CALIBRATION, *PLASMA flow, *ELECTRIC discharges, *HELIUM plasmas

Abstract

Information about charged particles emitted by plasma of high-current discharges is of interest both from the point of view of understanding the fundamental processes occurring in pulsed plasma and for applied problems. Compact magnetic spectrometers based on permanent magnets make it possible to measure the flux of charged particles from a plasma under conditions of strong electromagnetic noise. Imaging plates (IP) are one of the most commonly used types of detectors for detecting charged particles in laser-plasma and electric-discharge experiments. This paper presents the results of calibration of the BAS-MS IP when detecting electrons and the BAS-TR IP when detecting helium and tungsten ions. Calibration dependences of the sensitivity of the BAS-MS IP for electrons in the energy range of 0.65–50 MeV and the sensitivity of the BAS-TR IP for tungsten ions in the energy range from 20 eV to 650 keV are obtained, taking into account the angles of incidence of particles on the detector. [ABSTRACT FROM AUTHOR]

Published

2023

48. Measuring Impurity Concentration in Near Wall Plasma During Tests of Prototypes of the First Wall of Fusion Reactor in PLM Facility.

Author

Kavyrshin, D. I., Budaev, V. P., Fedorovich, S. D., Karpov, A. V., Chinnov, V. F., Lukashevsky, M. V., Tran, Q. V., Muravieva, E. A., Myazin, A. S., and Ageev, A. G.

Subjects

*FUSION reactors, *HELIUM plasmas, *MAGNETIC confinement, *MAGNETIC traps, *EMISSION spectroscopy, *OPTICAL spectroscopy, *PLASMA confinement

Abstract

This article describes the study of low pressure helium plasma with magnetic confinement at the experimental test setup at the Moscow Power Engineering Institute: plasma linear multicusp (PLM). This facility is intended for testing refractory materials and prototypes of elements of the first wall within the framework of development of the national fusion reactor (DEMO–FNS) and the International Thermonuclear Experimental Reactor (ITER). The facility provides the conditions of plasma impact on the surface of tested sample close to the parameters and regime of operation of tokamak divertor plates. The facility is a magnetic trap with minimum magnetic field on the axis, where the plasma is created by the flow of electrons moving from the directly heated tantalum cathode toward the anode. It is possible to create stationary helium plasma in the facility and to maintain it for several hours under constant discharge parameters: helium pressure in the chamber of 10–3–10–1 Torr, discharge current of 4–30 A, plasma column diameter of 35–40 mm, voltage drop across the discharge gap of 100–200 V. The thermal load on the surface of target introduced into the axial region of plasma column has reached 5 MW/m2. Optical emission spectroscopy is the main diagnostic tool in this work. The procedure for determining atomic concentrations from the data on the relative intensities of atomic spectral lines of metallic impurities is proposed in this work. [ABSTRACT FROM AUTHOR]

Published

2023

49. The production of reactive chlorine species (RCS) by argon and helium plasma jets and the sensitivity of liver cancer cell HepG2 to RCS and H2O2 treatment.

Author

Raud, Sirli, Raud, Jüri, Aarik, Lauri, Jõgi, Indrek, Kivimäe, Markus, Piller, Carl‐Thomas, Plaas, Mario, Plank, Toomas, Talviste, Rasmus, Teesalu, Tambet, and Vasar, Eero

Subjects

*PLASMA jets, *ARGON plasmas, *LIVER cells, *LIVER cancer, *CANCER cells, *HELIUM plasmas

Abstract

The present study investigated the production of reactive chlorine species (RCS) by Ar/O2 and He/O2 radiofrequency plasma jets in saline solution, and the sensitivity of the liver cancer cell line HepG2 to RCS and H2O2. Both plasma jets were able to produce RCS; however, at similar plasma powers, pressures, and feed gas flow rates, the He/O2 jet was more efficient for RCS production. The lower RCS yield in the case of the Ar/O2 plasma jet was mainly due to the higher RCS quenching. At a low production rate, RCS can be produced in the open air. Viability tests showed that HepG2 cells were more sensitive to H2O2 than RCS. [ABSTRACT FROM AUTHOR]

Published

2023

50. Tungsten Material Behavior under H 2 , D 2 , and He Plasma Interaction Conditions in the Framework of Fusion-Relevant Studies.

Author

Stancu, Cristian, Marascu, Valentina, Bonciu, Anca, Bercea, Adrian, Stoica, Silviu Daniel, and Constantin, Catalin

Subjects

*HELIUM plasmas, *PLASMA interactions, *TUNGSTEN, *DEUTERIUM plasma, *PLASMA flow, *HYDROGEN plasmas, *EMISSION spectroscopy, *DEUTERIUM

Abstract

In the current study, bulk tungsten material surfaces are exposed to hydrogen, deuterium, and helium plasmas in the radiofrequency domain (13.56 MHz) at an input power of 250 W using the hollow-cathode configuration. The ejected material is collected on titanium substrates at various distances (from 6 mm up to 40 mm). Therefore, the exposed tungsten materials are investigated for surface changes (blister occurrence, dust formation, or nano-structuration), along with the crystallinity, depending on the plasma's exposure times (from 30 min up to 120 min for each plasma type). Also, the collected materials are analyzed (morphological, structural, and statistical investigations) for dust and dust film-like appearance. Plasma discharges are analyzed using two methods: optical emission spectroscopy, and single Langmuir probes, to emphasize the nature of the used plasmas (cold discharges, ~2 eV), along with the presence of tungsten emission (e.g., WI 406.31 nm, WI 421.31 nm) during the plasma lifetime. By using a dedicated protocol, a method was established for obtaining fusion-relevant tungsten surfaces in the hydrogen and deuterium plasma discharges. By using the implemented method, the current paper introduces the possibility of obtaining a new tungsten morphology, i.e., the dandelion-like shape, by using helium plasma, in which the W18O49 compound can be found. [ABSTRACT FROM AUTHOR]

Published

2023